Selected renal cells harbor nephrogenic potential.

Selected renal cells (SRCs), a renal epithelial cell-enriched platform, are being advanced as an autologous cell-based therapy for the treatment of chronic kidney disease. However, the mechanism underlying its renal reparative and restorative effects remains to be fully elucidated. In this study, we coupled knowledgebase data with empirical findings to demonstrate that genes differentially expressed by SRCs form interactomes within tubules and glomeruli and mediate a suite of renal developmental activities including epithelial cell differentiation, renal vasculature development, and glomerular and nephron development. In culture, SRCs form organoids which self-assemble into tubules in the presence of a scaffold. Implanted into the kidneys of subtotally nephrectomized rats, SRCs are associated with comma- and S-shaped body cell formation and glomerular development, and improvement in renal filtration indices and renal microarchitecture. These data suggest that SRCs harbor nephrogenic potential, which may explain, at least in part, their therapeutic activity.

Cross-linked gelatin microspheres with continuously tunable degradation profiles for renal tissue regeneration.

Collagen and gelatin-based biomaterials are widely used in tissue engineering applications. Various methods have been reported for the cross-linking of these macromolecules for the purpose of delaying their biodegradation to prolong their in vivo residence (in tissue engineering applications) or tailoring their drug releasing capacity (when used as drug carriers). In this study, a carbodiimide-based cross-linking method, also used in the production of United States Food and Drug Administration-approved products, was employed to obtain differentially cross-linked gelatin beads. The colorimetric determination of the in vitro enzymatic susceptibility of the beads indicated that the resistance to degradation linearly correlated with the concentration of carbodiimide used for the cross-linking reaction. This result was also confirmed in vivo by the histological evaluation of the residence time of orthotopically injected cell-seeded beads. These data would indicate that the production of gelatin-based microbeads with tunable degradation profiles might be applicable toward the development of products that catalyze regeneration of kidney and other solid organs.

Fabrication of a multi-layer three-dimensional scaffold with controlled porous micro-architecture for application in small intestine tissue engineering.

Various methods can be employed to fabricate scaffolds with characteristics that promote cell-to-material interaction. This report examines the use of a novel technique combining compression molding with particulate leaching to create a unique multi-layered scaffold with differential porosities and pore sizes that provides a high level of control to influence cell behavior. These cell behavioral responses were primarily characterized by bridging and penetration of two cell types (epithelial and smooth muscle cells) on the scaffold in vitro. Larger pore sizes corresponded to an increase in pore penetration, and a decrease in pore bridging. In addition, smaller cells (epithelial) penetrated further into the scaffold than larger cells (smooth muscle cells). In vivo evaluation of a multi-layered scaffold was well tolerated for 75 d in a rodent model. This data shows the ability of the components of multi-layered scaffolds to influence cell behavior, and demonstrates the potential for these scaffolds to promote desired tissue outcomes in vivo.

Tissue engineering of esophagus and small intestine in rodent injury models.

Regenerative constructs composed of synthetically sourced, biodegradable biomaterials seeded with smooth muscle-like cells have been leveraged to mediate regeneration of bladder and bladder-like neo-organs. Here, we describe how such constructs may be applied to catalyze regeneration of esophagus and small intestine in preclinical rodent models.

Histological evaluation of tissue regeneration using biodegradable scaffold seeded by autologous cells for tubular/hollow organ applications.

The accurate interpretation of histological outcomes is a critical endpoint in preclinical studies. Thus, the toxicologic pathologist plays a vital role in conducting a comprehensive microscopic evaluation that would ultimately help defining the safety and functionality in Tissue Engineering/Regenerative Medicinal (TERM) products. In spite of many advances in regenerative medicine, there are no specific guidelines for the histological assessment of TERM products (Jayo et al. Toxicol Pathol 36:92-96, 2008). In this chapter, we describe the methodology designed to facilitate the detection of structural and functional changes when conducting a histological assessment including tissue collection (test article extraction), sampling, processing and fixation, special stains, statistical analysis, and morphometry.

Functional evaluation of primary renal cell/biomaterial neo-kidney augment prototypes for renal tissue engineering.

Development of a tissue-engineered neo-kidney augment (NKA) requires evaluation of defined, therapeutically relevant cell and cell/biomaterial composites (NKA constructs) for regenerative potential in mammalian kidney. Previous work identified primary renal cell populations that extended survival and improved renal function in a rodent model of chronic kidney disease (CKD). This study extends that work toward the goal of developing NKA by (i) screening in vivo inflammatory and fibrotic responses to acellular biomaterials delivered to healthy rodent renal parenchyma, (ii) evaluating the functionality of renal cell/biomaterial combinations in vitro, (iii) generating NKA constructs by combining therapeutically relevant cell populations with biocompatible biomaterial, and (iv) evaluating in vivo neokidney tissue development in response to NKA constructs delivered to healthy rodent renal parenchyma. Gelatin and hyaluronic acid (HA)-based hydrogels elicited the least inflammatory and fibrotic responses in renal parenchyma relative to polycaprolactone (PCL) and poly(lactic-co-glycolic acid) (PLGA) beads or particles and were associated with neovascularization and cellular infiltration by 4 weeks postimplantation. Renal cell populations seeded onto gelatin or HA-based hydrogels were viable and maintained a tubular epithelial functional phenotype during an in vitro maturation of 3 days as measured by transcriptomic, proteomic, secretomic, and confocal immunofluorescence assays. In vivo delivery of cell-seeded NKA constructs (bioactive renal cells + gelatin hydrogels) to healthy rodent renal parenchyma elicited neokidney tissue formation at 1 week postimplantation. To investigate a potential mechanism by which NKA constructs could impact a disease state, the effect of conditioned media on TGF-ß signaling pathways related to tubulo-interstitial fibrosis associated with CKD progression was evaluated. Conditioned medium was observed to attenuate TGF-ß-induced epithelial-mesenchymal transition (EMT) in vitro in a human proximal tubular cell line (HK2).

Isolation, characterization, and expansion methods for defined primary renal cell populations from rodent, canine, and human normal and diseased kidneys.

Chronic kidney disease (CKD) is a global health problem; the growing gap between the number of patients awaiting transplant and organs actually transplanted highlights the need for new treatments to restore renal function. Regenerative medicine is a promising approach from which treatments for organ-level disorders (e.g., neurogenic bladder) have emerged and translated to clinics. Regenerative templates, composed of biodegradable material and autologous cells, isolated and expanded ex vivo, stimulate native-like organ tissue regeneration after implantation. A critical step for extending this strategy from bladder to kidney is the ability to isolate, characterize, and expand functional renal cells with therapeutic potential from diseased tissue. In this study, we developed methods that yield distinct subpopulations of primary kidney cells that are compatible with process development and scale-up. These methods were translated to rodent, large mammal, and human kidneys, and then to rodent and human tissues with advanced CKD. Comparative in vitro studies demonstrated that phenotype and key functional attributes were retained consistently in ex vivo cultures regardless of species or disease state, suggesting that autologous sourcing of cells that contribute to in situ kidney regeneration after injury is feasible, even with biopsies from patients with advanced CKD.

Tubular cell-enriched subpopulation of primary renal cells improves survival and augments kidney function in rodent model of chronic kidney disease.

Established chronic kidney disease (CKD) may be identified by severely impaired renal filtration that ultimately leads to the need for dialysis or kidney transplant. Dialysis addresses only some of the sequelae of CKD, and a significant gap persists between patients needing transplant and available organs, providing impetus for development of new CKD treatment modalities. Some postulate that CKD develops from a progressive imbalance between tissue damage and the kidney's intrinsic repair and regeneration processes. In this study we evaluated the effect of kidney cells, delivered orthotopically by intraparenchymal injection to rodents 4-7 wk after CKD was established by two-step 5/6 renal mass reduction (NX), on the regeneration of kidney function and architecture as assessed by physiological, tissue, and molecular markers. A proof of concept for the model, cell delivery, and systemic effect was demonstrated with a heterogeneous population of renal cells (UNFX) that contained cells from all major compartments of the kidney. Tubular cells are known contributors to kidney regeneration in situ following acute injury. Initially tested as a control, a tubular cell-enriched subpopulation of UNFX (B2) surprisingly outperformed UNFX. Two independent studies (3 and 6 mo in duration) with B2 confirmed that B2 significantly extended survival and improved renal filtration (serum creatinine and blood urea nitrogen). The specificity of B2 effects was verified by direct comparison to cell-free vehicle controls and an equivalent dose of non-B2 cells. Quantitative histological evaluation of kidneys at 6 mo after treatment confirmed that B2 treatment reduced severity of kidney tissue pathology. Treatment-associated reduction of transforming growth factor (TGF)-ß1, plasminogen activator inhibitor (PAI)-1, and fibronectin (FN) provided evidence that B2 cells attenuated canonical pathways of profibrotic extracellular matrix production.

A comparison of experimental aneurysm occlusion determination by angiography, scanning electron microscopy, MICROFIL perfusion, and histology.

In clinical practice, occlusion of embolized, intracerebral aneurysms is evaluated using angiography. Standard, two-dimensional digital subtract angiography (DSA) is unable to quantify irregular aneurysm remnants, and even three-dimensional rotational angiography cannot quantify the degree of occlusion. To better understand occlusion at the aneurysm neck, we compared angiographic results with MICROFIL perfusion, histology, and scanning electron microscopy (SEM) results in 20 elastase-induced saccular aneurysms in rabbits. Aneurysms were embolized with HydroCoil devices (n = 12) or platinum coils (n = 8). Aneurysm follow-up occurred at 2 (n = 10) and 6 (n = 10) weeks. Aneurysm occlusion was evaluated using DSA, MICROFIL perfusion, histological ground sections, and SEM. Groups were compared statistically using ANOVA and chi(2) tests. The MICROFIL perfusion results were not concordant with the angiographic results for the HydroCoil and platinum coil groups. Both increased and decreased occlusion was observed on the MICROFIL-perfused aneurysms when compared with angiography. The histologic occlusion results of the HydroCoil group were concordant with the angiographic results; however, unoccluded areas not visible on angiography were routinely observed on the ground sections in the platinum coil group. SEM imaging of the aneurysm neck consistently showed decreased occlusion than angiographic results for both the HydroCoil and platinum coil groups. Although histology and MICROFIL-perfusion analyses provided additional details of aneurysm occlusion when compared with angiography, complete visualization of the entire neck of the aneurysm and accurate assessment of aneurysm occlusion was possible only with SEM.

A novel bioengineered small-caliber vascular graft incorporating heparin and sirolimus: excellent 6-month patency.

OBJECTIVE: A bioengineered microporous polycarbonate-siloxane polyurethane graft has been developed for coronary artery bypass grafting. Biological agents can be impregnated into its absorbable collagen and hyaluronan microstructure and stable macrostructure to promote patency. The objective of this study was to examine the in vivo biological performance and biomechanical characteristics of this graft. METHODS: Three types of graft (3.6-mm internal diameter, 24-mm length) were manufactured: heparin alone (H) grafts, heparin and sirolimus (HS) grafts, and grafts without any drug impregnation (C). All H and HS grafts were impregnated with 54 U of heparin in the microstructure for early elution to prevent acute graft thrombosis and 56 U of heparin in the macrostructure to prevent late thrombosis. In addition to the heparin, the HS graft was impregnated with 2.1 mg of sirolimus in the macrostructure for prolonged elution to inhibit intimal hyperplasia. All grafts (3.6-mm internal diameter, 24-mm length) were implanted into the abdominal aortas of rabbits (n = 55). Expanded polytetrafluoroethylene grafts (4.0-mm internal diameter, 24-mm length; n = 7) were implanted as controls. At 1, 3, and 6 months after surgery, the grafts were removed for histologic, scanning electron microscopic, immunohistochemical, and biomechanical evaluations. RESULTS: The patency rate was 100% in the H, HS, and C grafts at each time point. Although the expanded polytetrafluoroethylene grafts were patent at 1 and 3 months after surgery, 1 of 2 grafts (50%) were occluded at 6 months. None of the H or HS grafts had any stenosis or thrombus. Scanning electron microscopic examination proved that endothelial cells propagated smoothly from the anastomotic sites after 6 months in the H and HS grafts in comparison with the expanded polytetrafluoroethylene grafts, which had rare endothelialization. Neointima formation was inhibited in the HS graft compared with the H or C graft at 6 months (123 +/- 126 microm vs 206 +/- 158 microm or 202 +/- 67 microm; P < .05). In addition, the H, HS, and C grafts had greater cellular infiltration inside the graft than the expanded polytetrafluoroethylene grafts. All grafts except the expanded polytetrafluoroethylene graft had marked neocapillary formation 6 months after surgery. The graft compliance between 80 and 120 mm Hg was 6.0% +/- 2.5% and 6.2% +/- 0.9% at 6 months in the H and HS grafts, respectively. The graft macrostructure was unchanged according to the biomechanical evaluation in the H and HS grafts. CONCLUSION: A unique drug-eluting graft had excellent patency throughout the 6 months after implantation. The heparin-sirolimus graft encouraged luminal endothelialization without excessive intimal hyperplasia. This graft performed significantly better than the expanded polytetrafluoroethylene graft. This graft has the potential to become an implantable graft for coronary artery bypass grafting.

Novel bioengineered small caliber vascular graft with excellent one-month patency.

BACKGROUND: A bioengineered microporous polycarbonate-siloxane polyurethane graft has been developed for coronary artery bypass grafting. Biological agents can be impregnated into its absorbable collagen and hyaluronan microstructure and stable macrostructure to promote patency. The objective of this study was to examine the biological performance and biomechanical characteristics of this graft. METHODS: Heparin-sirolimus (HS) or heparin-sirolimus-vascular endothelial growth factor (HSV) grafts were manufactured for this study. Heparin (40 U) was embedded in the microstructure of the graft for early elution from the graft wall. Heparin (100 U) and sirolimus (450 microg) were incorporated into the macrostructure of the graft for late elution. Vascular endothelial growth factor was also embedded in the microstructure of the graft. Both grafts (3.6 mm internal diameter, 24 mm length) were implanted into the abdominal aortas of rabbits (n = 36) to compare with heparin-alone (H) grafts (n = 9). At 4 hours, 1 day, and 1, 2, and 4 weeks after surgery, the grafts were removed for histologic, immunohistochemical, and biomechanical evaluations. RESULTS: The patency rate of all grafts was 100% at each time point. None of grafts had stenosis after surgery. Endothelial cells were observed at 4 weeks after surgery in the HS, HSV, and H grafts. Although there was no significant difference of neointima thickness among the HS, HSV, and H grafts (136 +/- 75, 93 +/- 64, and 125 +/- 90 microm; p = 0.08), the H grafts did have more cellular infiltration in the graft than the HS or HSV grafts. There was neocapillary formation inside the graft wall at 4 weeks in all grafts. The graft macrostructure was unchanged based on biomechanical evaluation 4 weeks after surgery. CONCLUSIONS: A unique drug-eluting graft had excellent patency at 1 month and may encourage luminal endothelialization without excessive intimal hyperplasia. Although vascular endothelial growth factor did not improve intimal formation, cell infiltration, or vascularization, sirolimus might inhibit cell proliferation. Further long-term study would need to evaluate the efficacy of impregnated sirolimus.

Evaluation of a novel endoluminal vascular occlusion device in a porcine model: early and late follow-up.

PURPOSE: To evaluate the efficacy of a new vascular occlusion device (VOD) in a preclinical controlled study versus embolization coils. METHODS: The Biomerix VOD was made from a biodurable porous polyurethane matrix in the shape of a cylinder measuring 1.5 cm long by 6.0 mm wide. Thirty-three swine were selected to undergo embolization of a 3 to 5-mm-diameter iliac artery using either a single VOD (27 animals) or sufficient Cook fibered stainless steel coils to achieve angiographic occlusion (6 controls). Test animals were assigned to undergo angiography at 1 week (n=11), 1 month (n=6), 3 months (n=6), or 6 months (n=4). Two control animals were assigned to angiographic follow-up at 1 week, 1 month, and 3 months. Test and control animals were euthanized at each time point to explant occluded vessels for histological analysis. Study endpoints were device utilization, time to occlusion, postdeployment migration, and persistent angiographic occlusion at 7, 30, 90, and 180 days. RESULTS: One VOD was deployed in each test animal, whereas a mean 3.3+/-0.8 coils were needed to achieve angiographic occlusion in the 6 controls (p<0.001). The time to occlusion was significantly shorter with the VOD (1.46+/-0.73 versus 5.83+/-1.60 minutes for the coils; p<0.001). There was no evidence of recanalization or filling defects at the site of VOD deployment, while filling defects were seen in 3 of 6 coil-treated controls. The VOD arm showed superior angiographic occlusion versus coils at the 1-week, 1-month, and 3-month angiographic follow-up time points. Histological evaluation showed that the VOD was equivalent to the embolization coils at the 1-week (n=6) and 1-month (n=6) endpoint (100% luminal occlusion). In the 3-month group (n=6), the VOD showed 95% to 100% luminal occlusion versus 90% to 95% in the control animals. In the 6-month group, VOD showed 85% to 95% occlusion. CONCLUSIONS: The Biomerix VOD appears highly effective and reliable, resulting in significantly faster and longer lasting occlusion compared with fibered stainless steel embolization coils.